Abstract
Thermal-responsive surfaces are commonly existing in the living system and widely used in the practical applications. Recently, thermal-responsive superwetting surfaces have aroused worldwide interest and made big progress in fundamental research and practical applications in smart controllable fluid devices. This chapter focuses on the thermal-responsive superwetting surfaces and their applications, particularly on the switchable wettability on different thermal-responsive surfaces, the superwetting surfaces at high and low temperatures, the cooperation of temperature and other stimulus-responsive superwetting surfaces and the applications of thermal-responsive superwetting surfaces including the movement of liquid droplet, switchable surfaces adhesion and oil/water separation by temperature driving. Finally, we will briefly address personal points of the future development and remaining challenges of the thermal-responsive superwetting surfaces.
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Acknowledgments
The authors are grateful for financial support from the Chinese National Natural Science Foundation (21671012, 21373001, 21601013), Beijing Natural Science Foundation (2172033), the 973 Program (2013CB933004), the Fundamental Research Funds for the Central Universities, and the 111 Project (B14009).
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Tian, D., He, L., Jiang, L. (2018). Thermal-Responsive Superwetting Surface. In: Hozumi, A., Jiang, L., Lee, H., Shimomura, M. (eds) Stimuli-Responsive Dewetting/Wetting Smart Surfaces and Interfaces. Biologically-Inspired Systems, vol 11. Springer, Cham. https://doi.org/10.1007/978-3-319-92654-4_4
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